Unit 14 Ch. 28 Nuclear Chemistry I. The Nucleus II III IV
A. Mass Defect Difference between the mass of an atom and the mass of its individual particles. 4.00260 amu 4.03298 amu
B. Nuclear Binding Energy Energy released when a nucleus is formed from nucleons. High binding energy = stable nucleus. E = mc2 E: energy (J) m: mass defect (kg) c: speed of light (3.00×108 m/s)
B. Nuclear Binding Energy Unstable nuclides are radioactive and undergo radioactive decay.
UNIT 14 Ch. 28 Nuclear Chemistry II. Radioactive Decay II III IV
A. Types of Radiation 2+ 1- 1+ Alpha particle () Beta particle (-) helium nucleus paper 2+ Beta particle (-) electron 1- lead Positron (+) positron 1+ concrete Gamma () high-energy photon
B. Nuclear Decay Numbers must balance!! Alpha Emission parent nuclide daughter nuclide alpha particle Numbers must balance!!
B. Nuclear Decay Beta Emission electron Positron Emission positron
B. Nuclear Decay Electron Capture electron Gamma Emission Usually follows other types of decay. Transmutation One element becomes another.
B. Nuclear Decay Why nuclides decay… need stable ratio of neutrons to protons DECAY SERIES TRANSPARENCY
C. Half-life Half-life (t½) Time required for half the atoms of a radioactive nuclide to decay. Shorter half-life = less stable.
C. Half-life mf: final mass mi: initial mass n: # of half-lives
C. Half-life t½ = 5.0 s mf = mi (½)n mi = 25 g mf = (25 g)(0.5)12 Fluorine-21 has a half-life of 5.0 seconds. If you start with 25 g of fluorine-21, how many grams would remain after 60.0 s? GIVEN: t½ = 5.0 s mi = 25 g mf = ? total time = 60.0 s n = 60.0s ÷ 5.0s =12 WORK: mf = mi (½)n mf = (25 g)(0.5)12 mf = 0.0061 g
UNIT 14 Nuclear Chemistry III. Fission & Fusion II III IV
A. F ission splitting a nucleus into two or more smaller nuclei 1 g of 235U = 3 tons of coal
A. F ission chain reaction - self-propagating reaction critical mass - mass required to sustain a chain reaction
B. Fusion combining of two nuclei to form one nucleus of larger mass thermonuclear reaction – requires temp of 40,000,000 K to sustain 1 g of fusion fuel = 20 tons of coal occurs naturally in stars
C. Fission vs. Fusion 235U is limited danger of meltdown toxic waste thermal pollution fuel is abundant no danger of meltdown no toxic waste not yet sustainable
UNIT 14 Nuclear Chemistry IV. Applications II III IV
A. Nuclear Power Fission Reactors Cooling Tower
A. Nuclear Power Fission Reactors
A. Nuclear Power Fusion Reactors (not yet sustainable)
A. Nuclear Power Fusion Reactors (not yet sustainable) National Spherical Torus Experiment Tokamak Fusion Test Reactor Princeton University
B. Synthetic Elements Transuranium Elements elements with atomic #s above 92 synthetically produced in nuclear reactors and accelerators most decay very rapidly
C. Radioactive Dating half-life measurements of radioactive elements are used to determine the age of an object decay rate indicates amount of radioactive material EX: 14C - up to 40,000 years 238U and 40K - over 300,000 years
Radiation treatment using D. Nuclear Medicine Radioisotope Tracers absorbed by specific organs and used to diagnose diseases Radiation Treatment larger doses are used to kill cancerous cells in targeted organs internal or external radiation source Radiation treatment using -rays from cobalt-60.
E. Nuclear Weapons Atomic Bomb Hydrogen Bomb chemical explosion is used to form a critical mass of 235U or 239Pu fission develops into an uncontrolled chain reaction Hydrogen Bomb chemical explosion fission fusion fusion increases the fission rate more powerful than the atomic bomb
F. Others Food Irradiation Radioactive Tracers Consumer Products radiation is used to kill bacteria Radioactive Tracers explore chemical pathways trace water flow study plant growth, photosynthesis Consumer Products ionizing smoke detectors - 241Am